Piggyback programming using an extended first pulse for multi-level cell flash memory designs

ABSTRACT

A method of programming a memory cell that has 2 N  voltage levels where N&gt;1 and represents the number of bits stored within the memory cell. The method includes generating a first programming pulse, generating a second programming pulse subsequent to the generating the first programming pulse, wherein the first programming pulse has a width that is greater than the second programming pulse and programming at least two of the 2 N  voltage levels with the first programming pulse.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to the field of non-volatile memory devices. More particularly, the invention relates to a method of programming multi-bit flash electrically erasable programmable read only memory (EEPROM) cells that utilize the phenomena of hot electron injection to trap charge within a trapping dielectric material within the gate.

2. Discussion of Related Art

Memory devices for non-volatile storage of information are currently in widespread use today, being used in a myriad of applications. A few examples of non-volatile semiconductor memory include read only memory (ROM), programmable read only memory (PROM), erasable programmable read only memory (EPROM), electrically erasable programmable read only memory (EEPROM) and flash EEPROM.

Semiconductor EEPROM devices involve more complex processing and testing procedures than ROM, but have the advantage of electrical programming and erasing. Using EEPROM devices in circuitry permits in-circuit erasing and reprogramming of the device, a feat not possible with conventional EPROM memory.

Flash EEPROMs are similar to EEPROMs in that memory cells can be programmed (i.e., written) and erased electrically but with the additional ability of erasing all memory cells at once, hence the term flash EEPROM. A Flash device is a non-volatile memory comprising an array of cells that can store a pre-determined number of logic “0”'s and “1”'s. The stored “1”s and “0”s maintain their state in the absence of external power. These bits can be modified millions of times over the life-time of the device.

An example of a typical configuration for an integrated circuit including a multi-level cell flash memory array 100 and circuitry enabling programming, erasing, and reading for memory cells in the array 100 is shown in FIG. 1. The flash memory array 100 includes individual cells 102. Each cell 102 has a drain connected to a bitline 104, each bitline being connected to a bitline pull up circuit 106 and column decoder 108. The sources of the array cells are connected to Vss, while their gates are each connected by a wordline 109 to a row decoder 110.

The row decoder 110 receives voltage signals from a power supply 112 and distributes the particular voltage signals to the wordlines as controlled by a row address received from a processor or state machine 114. Likewise, the bitline pull up circuit 106 receives voltage signals from the power supply 112 and distributes the particular voltage signals to the bitlines as controlled by a signal from the processor 114. Voltages provided by the power supply 112 are provided as controlled by signals received from processor 114.

The column decoder 108 provides signals from particular bitlines 104 to sense amplifiers or comparators 116 as controlled by a column address signal received from processor 114. The sense amplifiers 116 further receive voltage reference signals from reference 118. The outputs from sense amplifiers 116 are then provided through data latches or buffers 120 to processor 114.

As mentioned above, the memory array 100 includes multi-level storage cells 102. Multi-level storage refers to the ability of a single memory cell 102 to represent more than a single binary bit of data. A conventional memory cell depicts two states or levels, usually referred to as logic “0” and logic “1”. A multi-level cell could represent as many as 256 states, or a byte of information.

Multi-level cell storage is obtainable in flash design because a flash memory cell can be programmed to provide multiple threshold voltage (vt) levels. The different vt levels can be sustained over time in a flash memory cell 102, even after repeated accesses to read data from the cell. For example, 16 vt levels stored in a flash memory cell can represent data in four conventional memory cells. Thus, an array of multi-level flash memory cells 102 which can store up to 16 vt levels can provide 4 times the storage capacity of conventional memory cells which only store a binary bit per cell. An example of a multi-level memory array is discussed in U.S. Pat. No. 5,973,958, the entire contents of which are incorporated herein by reference.

Programming of the flash memory array 100 is executed on a word-line basis. The word-line 109 is considered the row address. The word-line will cross multiple bit-lines 104. The bit-line 104 is considered the column address. Each bit-line 104 contains buffer logic to interface to the selected core cell during program, read and erase operations.

FIG. 2 illustrates a selected and unselected bit-line during programming. The unselected bit (bit not to be programmed) is considered inhibited. The bit-line is inhibited from the effects of the program pulse. The selected bit (bit to be programmed) is referred to as uninhibited. This bit will be programmed during the program pulse.

To program a multi-level cell in the flash memory array 100, high gate-to-drain voltage pulses are provided to the cell from power supply 112 while a source of the cell is grounded. For instance, during programming typical gate voltage pulses of 18V are each applied to a cell, while a drain voltage of the cell is set to 3.3V and its source is grounded.

As shown in FIG. 2, the program voltage PVpp of 18V will be applied to the selected word-line (column address). A substantially lesser voltage, such as 10V, will be applied to unselected word-lines. An uninhibited word-line will have a strong field generated across the device. In particular, FIG. 2 shows that with Vss of 0V being applied to one end of a bit-line 109 to be uninhibited, the source/drain regions of the bit-line will couple to 0V or ground. This will make the applied field appear much stronger so that effective programming can occur. A high field generated across the memory device will cause electron injection into the floating gate of the selected cell exponentially proportional to strength of the field. This programming procedure results in an increase of a threshold voltage for the cell, the threshold being the gate-to-source voltage required for the cell to conduct.

Each programmed cell requires a specific amount of applied electric field to obtain the desired programmed vt level. The amount of electric field determines the program speed of a bit-cell. Fast cells will need less applied field while slow cells will need more. The electric field is applied through several program pulses. The use of program pulses allows the device to control program distributions. After each pulse, the cells are program-verified to see if the target vt has been achieved. Using multiple program pulses allows the device to stop programming fast bits while completing the programming the slow bits.

An inhibited word-line will not have a strong field across the device. FIG. 2 shows that with VCC=3.3V being applied at one end of a bit-line 109 to be inhibited, the source/drain regions of bit-line will couple to 8V. This will make the applied field appear much weaker and no effective programming will occur.

As explained above, a multi-level cell 102 utilizes 2^(N) VT levels to represent N logical bits. Standard program times of multi-level cell designs are 2^(N)−1 times that of a single bit program time (SBPT). An example of known programming of two logical bits (N=2) in a single multi-level cell 102 is shown in FIG. 3. In particular, four programming charge distributions A, B, C and E are formed. The centers of the programming charge distributions A-C are preferably positioned between the centers of the charge distributions for the reading pulses. The centers of the charge read distributions are labeled RdA, RdB and RdC corresponding to Read Level A, Read Level B and Read Level C, respectively. RdA typically has a value of approximately 0V, RdB a value of approximately 800 mV and RdC a value of approximately 1.6V. Besides wanting the centers of the program distributions A-C to be positioned between Read Levels A-C, it is desired that there be no intersection between the programming and read distributions so that the read process can accurately predict the levels of the memory cell are properly programmed.

Table 1 is given below that shows a preferred correspondence between the levels A-C and E and the accessed logical bit values Q1, Q2.

TABLE 1 Level Vt Q2 Q1 C 2.0 V 0 0 B 1.0 V 0 1 A 0 V 1 0 E < -2.0 V 1 1

Since charge distribution E is the erase state and considered the default setting, there are 2^(N)−1 levels or in the case of N=2 three levels A-C (2²−1) that must be programmed depending on loaded data. In a known manner of programming, each of the 2²−1 levels is programmed separately. Each level is programmed separately so that the inhibited and uninhibited bit-lines can be set. This separate programming results in the total programming time being equal to (2^(N)−1)*SBPT (single bit program time). As N, the number of logical bits increases, the programming time becomes exponentially larger and more burdensome. For example, a 4-bit (N=4) multi-level cell design can have a programming time that is 2⁴−1 times greater than that of a 2-bit multi-level cell design. Accordingly, there is a need for reducing the programming time for multi-level cells that are programmed for multiple bits.

Please note that in order to achieve the above programming one or more pulses are applied to each vt level separately. In the case of N=2, initially pulses of a voltage, such as 20V, are applied to the highest vt level C. After level C is programmed, one or more pulses of a voltage, such as 19V, are applied to the next lowest level B until level B is programmed. Next, one or more pulses of a lower voltage, such as 18V, are applied to the lowest level C until level C is programmed. Note that the voltages of the pulses are dependent on the desired speed of programming. Note that the highest vt level pulse is adjusted so that the selected bit cells will complete programming in ½ the pulse count of the successive vt levels. For example, if the pulse target is 10, the high vt level bits will be targeted for completion of programming in 5 pulses. If the high vt level programming speed increases (fewer pulses), the program voltage can be adjusted to slow successive level programming and insure proper distributions for the lower vt levels.

To erase a cell in the flash memory array 100, the programming process described above is reversed. In the case of N=2, the highest level vt level C is erased by applying pulses of 20V to the substrate while the gate is grounded.

To read the state of a cell, a typical control gate voltage of Rd levels is applied to the cell. The current output from the cell being read is received at an input of a number of the sense amplifiers 116 connected to the same bitline as the cell being read. A second input to each sense amplifier is provided from the reference 118. The reference 118 provides a different reference current to each sense amplifier connected to a bit line, with a current level set equal to current expected from a cell being read when programmed to a desired threshold voltage state. Binary outputs of the sense amplifiers 116 indicate if the cell being read is in a state that is greater than or less than the state of the reference signal received. Outputs of the sense amplifiers are provided through data latch/buffers 120 to the processor 114, enabling the processor 114 to determine from the sense amplifier outputs the threshold state of the cell being read.

SUMMARY OF THE INVENTION

One aspect of the present invention regards a method of programming a memory cell that has 2^(N) voltage levels where N>1 and represents the number of bits stored within the memory cell. The method includes generating a first programming pulse, generating a second programming pulse subsequent to the generating the first programming pulse, wherein the first programming pulse has a width that is greater than the second programming pulse and programming at least two of the 2^(N) voltage levels with the first programming pulse.

A second aspect of the present invention regards a method of programming a multi-level cell flash memory array that includes individual multi-level memory cells, wherein each of the individual memory cells has a drain connected to a bitline, a source connected to a voltage source Vss and a gate connected to a wordline. The method includes uninhibiting only a bitline corresponding to a voltage level of one of the individual multi-level memory cells, applying a first multi-step programming pulse to the uninhibited bitline and programming the voltage level with the first multi-step programming pulse. Applying second multi-step programming pulse to the uninhibited bitline and programming the voltage level with the second multi-step programming pulse, wherein the first multistep programming pulse differs in shape from the second multi-step programming pulse.

The above aspects of the present invention provide the advantage of reducing the programming times of a multi-level memory cell and memory array.

The above aspects of the present invention provide the advantage of providing improved programming distributions while reducing programming times.

The present invention, together with attendant objects and advantages, will be best understood with reference to the detailed description below in connection with the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 schematically illustrates an embodiment of an integrated circuit with a flash memory array that is programmed in a manner in accordance with the present invention;

FIG. 2 schematically shows a known method of programming the flash memory array of FIG. 1;

FIG. 3 schematically shows a known method of programming a multi-level cell used in the flash memory array of FIG. 1;

FIG. 4 shows an embodiment of a “standard piggyback” pulse that is used with a mode of programming in accordance with the present invention;

FIG. 5 shows an embodiment of an “extended piggyback” pulse that is used with a mode of programming in accordance with the present invention; and

FIG. 6 schematically shows a mode of programming the flash memory array of FIG. 1 with the “piggyback” pulses of FIGS. 4 and 5.

DETAILED DESCRIPTION OF THE INVENTION

The following description of the method of the present invention will be with respect to the multi-level memory array 100 shown in FIG. 1. It should be understood that the present invention can be applied to other embodiments of memory structures as well.

One mode of programming of the memory array 100 according to the present invention is accomplished by applying a single “piggyback” pulse 200 to the multi-level cell 102 as shown in FIG. 4 and as explained in U.S. patent application Ser. No. 09/779,821 entitled “Piggyback Programming Using Voltage Control For Multi-Level Cell Flash Memory Designs” by Allan Parker and filed concurrently with the present application, the entire contents of which are incorporated herein by reference. As will be explained in more detail below, applying a piggyback pulse using voltage control allows all 2^(N) levels to be programmed as a group thus drastically reducing the programming time. Though program time is reduced, this new methodology does not have a detrimental effect on program accuracy or cell reliability.

As shown in FIG. 4, one mode of piggyback programming begins with the highest level vt and steps its way down. Each step will reduce the program voltage in accordance to the level needed for the specific vt target. In FIG. 4, an example of programming of a memory cell with two bits is illustrated. The example takes into account that cell examination shows that the effective program strength doubles for every 0.5V added to the program voltage. Cell examination also indicates that it takes 4 times the work to program level B as level C bits. With the above said, the piggyback program voltage will step from 20, 19 and 18 volts. The high level voltage of 20 volts is explained by the fact that the high level C takes 4 times the work of level B and 16 times the work of level A. In addition, if it takes 10 pulses to program level A at 18V, it will take 40 pulses to program level B with the same voltage. At each step, specific bits will be enabled for programming. Of course, other values for the voltages of the pulses are possible depending on the desired speed of programming.

As shown in FIG. 6, the initial portion 202 of the pulse 200 has a voltage of 20 volts that corresponds to the vt value of level C. Thus, the initial portion 202 programs the level C data. During the application of portion 202, the bit line corresponding to level C is the only bit line uninhibited and selected for programming. The bit-lines corresponding to levels A and B are inhibited.

Upon completion of the initial portion 202 of the pulse 200, a second portion 204 of the pulse is applied. The second portion 204 is lowered to a program voltage of 19V that corresponds to the vt value of level B. During application of the second portion 204 of the pulse 200, a voltage Vss is applied to the bit line corresponding to level B so as to drain charge. The level B and level C bit-lines are both selected for programming during application of the second portion 204. This is not a problem because the level C bits are much harder to program at this stage and the second portion 204 will assist in level C programming. During application of the second portion 204, the bit lines corresponding to level A and the Erase State level are inhibited.

Upon completion of the second portion 204, a third portion 206 of the pulse is applied. The third portion 206 is lowered to a program voltage of 18V that corresponds to the vt value of level A. During application of the third portion 206 of the pulse 200, a voltage Vss is applied to the bit line corresponding to level A so as to drain charge. During application of the third portion 206, all three of the bit lines corresponding to the levels A, B and C are selected for programming. The level B and C bits are much harder to program at this stage and the third portion 204 will assist in level B and C programming. During application of the third portion 204, only the bit line corresponding to the Erase State level is inhibited.

After the pulse 200 is complete, the word-line and bit-line are discharged.

In summary, the above-described mode of programming includes the following principles:

1) When a bit-line has been uninhibited, the word-line voltages must be re-applied to inhibit. The coupling only occurs when word-lines are raised to the high voltages.

2) A bit-line can always be uninhibited by applying Vss to drain the charge away.

While the above described mode of piggyback programming leads to significant program saving when compared with known programming that uses separate pulses to program each vt level individually, the programming time can be further improved by applying a so-called “extended” first piggyback pulse 300 during programming in combination with later applied “standard” piggyback pulses 200 as described previously. A discussion of using an extended programming pulse in combination with a standard programming pulse is provided in commonly owned U.S. patent application Ser. No. 09/511,874 by Allan Parker, the entire contents of which are incorporated herein by reference.

An example of an extended piggyback pulse 300 to be used according to the present invention is shown in FIG. 5. The pulse 300 is “extended” in that it has portions 302, 304 and 306 that correspond exactly to portions 202, 204 and 206 except that they have voltage pulse widths that are greater than those of the corresponding portions 202, 204, 206. The voltage step magnitudes of portions 302, 304 and 306 are the same as portions 202, 204 and 206, respectively. The pulse widths of portions 302, 304 and 306 are larger from their corresponding portions 202, 204 and 206 by a common proportionality constant.

Key to successful multi-level cell operation is controlled program vt distributions. Hump width and spacing must fall within target windows for correct data storage and long term reliability. To achieve this programming control, a specific program pulse target is usually required. For example, 10-15 μsec pulses can be used to program level within a 250 mv distribution. The program voltage will then be set to insure 10 pulses during level 1 programming.

In piggyback programming, the applied program voltages are adjusted so that all levels should be complete after 10 piggyback pulses. Note that in the case of using multiple piggyback programming pulses for programming, the frequency of the piggyback programming pulses will of course depend on the verify pulse timing.

Program control must account for slow and fast bits. Due to variations in the bit-cell population, some bits can program in 7 pulses while others may need 10. Device analysis can monitor the disparity between the fast and slow bit-cells. This analysis will indicate a maximum speed that a bit-cell can obtain. For example, it may be found that every bit-cell requires at least 5 pulses to complete programming. This program cap is used to distinguish characteristics of an extended pulse.

With this information, the extended first pulse can be generated. In this example, the first pulse is made equivalent to 5 standard pulses. Examples of the step widths in μsec for a standard nonextended pulse and extended pulses that are equivalent to 4 and 5 standard pulses are given in Table 2 below. Note that the total time includes an additional 10 μsec for setup and discharge concerns.

TABLE 2 Pulse Level C Level B Level A Total Standard 7.5 8 10 35.5 4 Pulse Ext. 30 32 40 112 5 Pulse Ext. 50 40 37.5 137.5

Programming of the memory array 100 according to the present invention is accomplished by applying an extended first “piggyback” pulse 300 and a standard “piggyback” pulse 200 to the multi-level cell 102 as shown in FIGS. 4-6.

In particular, FIG. 6 illustrates the use of piggyback programming with an extended first piggyback pulse 300 in combination with a plurality of standard piggyback pulses 200. Programming is performed in a manner similar to that described above when only standard piggyback programming pulses 200 are used for programming. For example, the initial portion 302 of the pulse 300 has a voltage of 20 volts that corresponds to the vt value of level C. Thus, the initial portion 302 programs the level C data. During the application of portion 302, the bit line corresponding to level C is the only bit line uninhibited and selected for programming. The bit-lines corresponding to levels A and B are inhibited.

Upon completion of the initial portion 302 of the pulse 300, a second portion 304 of the pulse is applied. The second portion 304 is lowered to a program voltage of 19V that corresponds to the vt value of level B. During application of the second portion 304 of the pulse 300, a voltage Vss is applied to the bit line corresponding to level B so as to drain charge. The level B and level C bit-lines are both selected for programming during application of the second portion 304. This is not a problem because the level C bits are much harder to program at this stage and the second portion 304 will assist in level C programming. During application of the second portion 304, the bit lines corresponding to level A and the Erase State level are inhibited.

Upon completion of the second portion 304, a third portion 306 of the pulse is applied. The third portion 306 is lowered to a program voltage of 18V that corresponds to the vt value of level A. During application of the third portion 306 of the pulse 300, a voltage Vss is applied to the bit line corresponding to level A so as to drain charge. During application of the third portion 306, all three of the bit lines corresponding to the levels A, B and C are selected for programming. The level B and C bits are much harder to program at this stage and the third portion 304 will assist in level B and C programming. During application of the third portion 304, only the bit line corresponding to the Erase State level is inhibited. After the pulse 300 is complete, the word-line and bit-line are discharged.

The subsequent standard pulses 200 program the levels A-C in a manner similar to that described above with respect to extended pulse 300. After each pulse, the cells are program-verified to see if the target vt has been achieved.

The end result of using extended and standard piggyback pulses is that an electric field is applied through several pulse programs. The use of program pulses allows the device to control program distributions. Using multiple program pulses, allows the device to stop programming fast bits while completing the slow bit-cells. Applying piggyback pulses 200 and 300 using voltage control allows all 2^(N) levels to be programmed as a group thus drastically reducing the programming time. Though program time is reduced, this new methodology does not have a detrimental effect on program accuracy or cell reliability.

Table 3 illustrates the total program time for the three types of pulses illustrated in Table 2 when 10 total piggyback pulses are required for programming all vt levels. In Table 3, the number of pulses column includes the extended pulse and the needed standard pulses to complete programming. The program time will be the sum of the extended pulse width and (N−1)*the standard pulse width, where N is the number of pulses needed for programming all the vt levels. The evaluation (Eval) time is equal to the N*Program verify time, wherein the program-verify time is the time to verify each piggyback pulse and is assumed to be 12 μsec. Thus, the total programming time equals the sum of the program time and the evaluation time.

TABLE 3 Extended # Pulse Prog Eval Pulse Pulses Width Time Time Total Savings Standard 10 35.5 355 120 475 4 Pulse 7 112 325 84 409 14% Ext. 5 Pulse 6 137.5 315 72 387 19% Ext.

As shown in Table 3, use of an extended piggyback programming pulse that is equivalent to 4 standard piggyback programming pulses will lead to a 14 percent reduction in programming time when compared with using standard piggyback programming pulses. Similarly, use of an extended piggyback programming pulse that is equivalent to 5 standard piggyback programming pulses will lead to a 19 percent reduction in programming time when compared with using standard piggyback programming pulses. Table 3 illustrates that using an extended pulse generates program savings ranging from 14 to 19 percent through reduced setup/discharge penalties and a reduced number of program-verify evaluations. The actual savings will depend on the disparity between the fast and slow bits of a specific process and the choice of extended pulse width.

The foregoing description is provided to illustrate the invention, and is not to be construed as a limitation. Numerous additions, substitutions and other changes can be made to the invention without departing from its scope as set forth in the appended claims. For example, programming according to the present invention is scaleable to all multi-level cell densities. 

I claim:
 1. A method of programming a plurality of memory cells, wherein each of said memory cells has 2^(N) voltage levels where N>1 and represents the number of bits stored within said memory cell, the method comprising: applying a first programming pulse to a first of said memory cells, wherein said first programming pulse comprises 2^(N)−1 portions; applying a second programming pulse to said first of said memory cells subsequent to said first programming pulse, wherein said second programming pulse comprises 2^(N)−1 portions; wherein said first of said memory cells is programmed during one of said portions of said first programming pulse and one of said portions of said second programming pulse; and wherein said first programming pulse has a width that is greater than said second programming pulse.
 2. The method according to claim 1, further comprising: applying said first programming pulse to a second of said memory cells; applying said second programming pulse to said second of said memory cells subsequent to said first programming pulse; and wherein said second of said memory cells is programmed during another of said portions of said first programming pulse and another of said portions of said second programming pulse.
 3. The method according to claim 2, wherein programming of said second of said memory cells does not interfere with programming of said first of said memory cells.
 4. The method according to claim 1, wherein each portion of said first programming pulse is a stepped down voltage with respect to the previous portion of said first programming pulse.
 5. The method according to claim 1, wherein each portion of said second programming pulse is a stepped down voltage with respect to the previous portion of said second programming pulse.
 6. The method according to claim 1, wherein not all widths of said portions of said first programming pulse are equal.
 7. The method according to claim 1, wherein not all widths of said portions of said second programming pulse are equal.
 8. The method according to claim 1, wherein each of said portions of said first programming pulse corresponds to one of said voltage levels.
 9. The method according to claim 1, wherein each of said portions of said second programming pulse corresponds to one of said voltage levels.
 10. The method according to claim 1, wherein each of said portions of said first programming pulse corresponds to one of said portions of said second programming pulse.
 11. The method according to claim 10, wherein the width of each portion of said first programming pulse is greater than the width of a corresponding portion of said second programming pulse.
 12. The method according to claim 10, wherein the width of each portion of said first programming pulse is greater than the width of a corresponding portion of said second programming pulse by a common proportionality constant.
 13. The method according to claim 1, wherein said first programming pulse is equivalent to a plural number of said second programming pulses.
 14. The method according to claim 1, wherein said first programming pulse is equivalent to four of said second programming pulses.
 15. The method according to claim 1, wherein said first programming pulse is equivalent to five of said second programming pulses.
 16. The method according to claim 1, wherein said memory cells comprise EEPROM memory cells.
 17. The method according to claim 1, wherein said memory cells comprise flash EEPROM memory cells.
 18. The method according to claim 1, wherein improved programming distribution of said voltage levels is provided.
 19. The method according to claim 1, wherein the combined programming time of said first of said memory cells and said second of said memory cells is reduced.
 20. A method of programming an array of flash memory cells, wherein each of said flash memory cells has at least four voltage levels representing two or more bits stored within said flash memory cell, and wherein each of said flash memory cells comprises a drain connected to a bitline and a gate connected to a wordline, the method comprising: applying a first multi-step programming pulse to a wordline corresponding to a first of said flash memory cells and a wordline corresponding to a second of said flash memory cells, uninhibiting only a bitline corresponding to said first of said flash memory cells during a first step of said first multi-step programming pulse, wherein a first voltage level is programmed in said first of said flash memory cells; uninhibiting only a bitline corresponding to said second of said flash memory cells and said bitline corresponding to said first of said flash memory cells during a second step of said first multi-step programming pulse, wherein a second voltage level is programmed in said second of said flash memory cells; applying a second multi-step programming pulse to said wordline corresponding to said first of said flash memory cells and said wordline corresponding to said second of said flash memory cells; uninhibiting only said bitline corresponding to said first of said flash memory cells during a fist step of said second multi-step programming pulse, wherein said first voltage level is further programmed in said first of said flash memory cells; uninhibiting only said bitline corresponding to said second of said flash memory cells and said bitline corresponding to said first of said flash memory cells during a second step of said second multi-step programming pulse, wherein said second voltage level is further programmed in said second of said flash memory cells; and wherein said first multi-step programming pulse has a pulse width that is greater than said second multi-step programming pulse.
 21. The method according to claim 20, wherein said uninhibiting comprises applying a voltage of Vss to said bitlines.
 22. The method according to claim 20, further comprising discharging said wordlines and said bitlines after any of said multi-step programming pulse is complete.
 23. The method according to claim 20, wherein said first voltage level of said first of said flash memory cells is further programmed during said second step of said first multi-step programming pulse and said second step of said second multi-step programming pulse.
 24. The method according to claim 20, wherein each step of said first multi-step programming pulse corresponds to one of said voltage levels.
 25. The method according to claim 20, wherein the subsequent step of said first multi-step programming pulse is less than the previous step of said first multi-step programming pulse.
 26. The method according to claim 20, wherein the number of steps of said first multi-step programming pulse is equal to one less than the number of said voltage levels.
 27. The method according to claim 20, wherein each step of said second multi-step programming pulse corresponds to one of said voltage levels.
 28. The method according to claim 20, wherein the subsequent step of said second multi-step programming pulse is less than the previous step of said second multi-step programming pulse.
 29. The method according to claim 20, wherein the number of steps of said second multi-step programming pulse is equal to one less than the number of said voltage levels.
 30. The method according to claim 20, wherein the width of each step of said first multi-step programming pulse is larger than the width of a corresponding step of said second multi-step programming pulse by a common proportionality constant.
 31. The method according to claim 20, wherein said first multi-step programming pulse is equivalent to a plural number of said second multi-step programming pulse.
 32. The method according to claim 20, wherein said first multi-step programming pulse is equivalent to four of said second multi-step programming pulse.
 33. The method according to claim 20, wherein said first multi-step programming pulse is equivalent to five of said second multi-step programming pulse.
 34. The method according to claim 20, wherein said flash memory cells comprises an EEPROM memory cell.
 35. The method according to claim 20, wherein improved programming distribution of said voltage levels is provided.
 36. The method according to claim 20, wherein the combined programming time of said first of said flash memory cells and said second of said flash memory cells is reduced. 